Methods of making composite nonwoven webs

ABSTRACT

Disclosed herein are improvements to processes and equipment for the manufacture of composite nonwoven webs comprising a mixture of two or more different fibers and formed from at least two streams of air-entrained fibers. Adjacent the perimeter of an exit port of one of the fiber streams are located a series of spaced tabs and apertures. As a first stream of air-entrained fibers pass the series of tabs and apertures, vortices are formed therein. When mixed with a second stream of air-entrained fibers, the vortices within the first stream of fibers causes increased mixing of the fibers, helping to drive the first fibers deeper into the second stream of air-entrained fibers.

This application claims priority from U.S. provisional PatentApplication Ser. No. 62/527,326 filed on 30 Jun. 2017, the entirecontents of which are incorporated herein by reference.

FIELD OF INVENTION

The present invention relates to methods of making coherent nonwovenwebs comprising a mixture of two or more different fibers.

BACKGROUND

Various different methods are known in the art with regard to theformation of nonwoven webs. For example, nonwoven webs are known to bemade from various processes such as spunbonding, meltblowing,hydroentangling, carding and so forth. In addition, many of theseprocesses can be adapted so as to form nonwoven webs having combinationsof different fibers. For example, as is generally known, differentstreams of fibers can be introduced together and co-mingled to somedegree as described in U.S. Pat. No. 5,350,624 to Georger; U.S. Pat. No.5,853,635 Morell et al., U.S. Pat. No. 6,263,545 Pinto, and so forth.However, the degree and/or nature of mixing is not easily controlledwhen bringing distinct streams of fibers together at high rates. Whilemore aggressive mixing of fibers can be achieved by changing the angleof impingement, velocity and other aspects of the fiber streams, oftentimes such process conditions can also negatively impact otherattributes of the formed web such as softness, strength, integrity, etc.Thus, there is a need for an improved process that allows for greatercontrol over the mixing of distinct fiber streams yet does so withoutsacrificing other desired attributes of the formed nonwoven web.

Therefore, the present invention provides a process of inter-mixingdifferent streams of fibers that drives greater mixing of fibers andthat can be readily adapted to modify the degree and/or nature of mixingto be achieved for a given process.

SUMMARY OF THE INVENTION

The improved method of the present invention includes utilizing a chutehaving first and second opposed walls that define a passageway and anexit gap and further having a series of spaced tabs extending outwardlyadjacent the exit gap perimeter. The tabs may have a width of betweenabout 0.5 and about 10 cm and, between the tabs, an aperture or openspace whereby air is allowed to flow sidewardly relative to the to thedirection of passageway. First fibers are entrained in a first stream ofair and directed downwardly through the chute at a high velocity and outof the chute through the exit gap and adjacent tabs. As theair-entrained first fibers pass the series of tabs and apertures,vortices are formed within the air-entrained first fibers. Second fibersare separately entrained within a stream of air and, immediately belowthe exit gap, are directed to impinge upon the first stream ofair-entrained fibers wherein the second fibers and first fibersinter-mix and form a composite stream of air-entrained fibers. Theformation of the vortices within the first stream of fibers acts tocause increased mixing of the fibers, helping to drive the first fibersdeeper into the air-entrained stream of second fibers. Thereafter, thecomposite stream of air-entrained fibers are deposited onto a foraminousforming surface thereby forming a nonwoven web.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side view of a system for making a composite nonwoven webaccording to the present invention.

FIG. 2 is a perspective view of a vortex generator for use in thepresent invention.

FIGS. 3A, 3B and 3C are side views of different vortex generators asseen from the machine direction.

FIG. 4 is a side view of a system employing a vortex generator of thepresent invention.

DETAILED DESCRIPTION

Throughout the specification and claims, discussion of the methods,articles and/or individual components thereof is with the understandingset forth below.

(i) The term “comprising” or “including” or “having” are inclusive oropen-ended and do not exclude additional unrecited elements,compositional components, or method steps. Accordingly, the terms“comprising” or “including” or “having” encompass the more restrictiveterms “consisting essentially of” and “consisting of.”

(ii) As used herein “continuous fibers” means fibers formed in acontinuous, uninterrupted manner having a substantially indefinitelength and having a high aspect ratio (length to diameter) in excess of10,000:1.

(iii) As used herein “staple length fibers” means continuous syntheticfibers cut to length or natural fibers, such fibers having a lengthbetween about 0.5 mm and about 60 mm. The length of such fibers beingthat of the straight (e.g. uncontorted) fiber.

(iv) As used herein, unless expressly indicated otherwise, when used inrelation to material compositions the terms “percent” or “%” each referto the quantity by weight of a component as a percentage of the total.

(v) As used herein the term “cellulosic” means those materialscomprising or derived from cellulose including natural or syntheticcellulose as well as that derived from both woody and non-woody sources.

(vii) As used herein, the term “polymer” generally includes but is notlimited to, homopolymers, copolymers, such as for example, block, graft,random and alternating copolymers, terpolymers, etc. and blends andmodifications thereof. Furthermore, unless otherwise specificallylimited, the term “polymer” shall include all possible geometricalconfigurations of the molecule. These configurations include, but arenot limited to isotactic, syndiotactic and random symmetries.

(vii) As used herein “propylene polymer” means a polymer having greaterthan 50% propylene content.

(viii) As used herein, the term “nonwoven web” means a structure or aweb of material that has been formed without use of traditional fabricforming processes such as weaving or knitting, to produce a structure ofindividual fibers or threads that are entangled or intermeshed, but notin an identifiable, repeating manner.

(ix) As used herein, the term “machine direction” or “MD” refers to thedirection of travel of the forming surface onto which fibers aredeposited during formation of a fibrous web.

(x) As used herein, the term “cross-machine direction” or “CD” refers tothe direction which is essentially perpendicular to the machinedirection defined above.

Vortex Generator

As shown in reference to the schematic representation of FIG. 1, asystem 10 is shown for use in practicing the method of the presentinvention. A nozzle or chute 20 is provided having a first wall 22 and asecond wall 23 that defines a passageway 24 and a passageway direction26 (i.e. the direction in which the air and air-entrained fibers traveldownwardly through the chute). While two walls are shown for ease ofreference, it will be readily appreciated that they system can haveadditional opposed walls and provide a chute that is fully enclosedalong its height. With respect to closed chute systems, typically thepassageway would have a rectangular configuration and in such respectthe first and second walls referenced herein would correspond to thelonger walls defining the rectangular chute and that extend in thecross-direction. The length of the first and second walls, i.e. thelength extending in the cross-direction, can vary significantlyincluding for example having lengths between about 0.5 and about 5 M oreven between about 1M and about 3 M. The height of the walls 22, 23,i.e. the length of the passageway 24 spanning the feed gap 28 and exitgap 30, can be about 4 M or less. The passageway 24 has a feed gap 28,where the fiber stream is introduced into the passageway 24, and an exitgap 30 where the fiber stream exists the passageway 24. The exit gap 30can have a gap width, i.e. the distance between the first and secondwalls 22, 23, of between about 0.5 cm and about 15 cm. It will bereadily understood that, in a fully enclosed chute, third and fourthwalls extending in the machine direction would span the gap between andthe first and second walls and be adjoined therewith to define theperimeter of the chute.

Adjacent the exit gap 30 is a vortex generator 40. As best seen inrelation to FIGS. 2 and 3, the vortex generator comprises a series ofspaced tabs 42 adjacent the perimeter 31 of the exit gap 30. The tabs 42extend outwardly parallel or substantially parallel with the passagewaydirection 24. In one aspect, the tabs may extend at an angle +/−45degrees relative to the passageway direction 26, between about +/−30degrees relative to the passageway direction 26 or between +/−15 degreesrelative to the passageway direction 26. In certain embodiments, thetabs may be hinged or adjustable such that their angle relative to thepassageway direction may be easily changed. In certain embodiments, thetabs may be positioned to be flush with the exit gap 30 or inner wall 22a of the chute. Alternatively, the tabs may be positioned slightly backfrom the perimeter of the exit gap 30. In certain embodiments, the tabscan be positioned so as to be flush with the perimeter of the exit gap(i.e. flush with the inner walls 22 a) and are angled such that theyeither extend (i) parallel with the passageway direction, (ii) parallelwith the plane of the adjacent passageway inner wall, (iii) outwardly,such as away from the plane of the adjacent passageway inner wall oraway from the first stream, or (iv) inwardly, such as away from theouter wall or towards the first stream. In still further embodiments,the base of the tabs may be positioned slightly outwardly or back fromthe exit gap perimeter and either extend (i) parallel with thepassageway direction, (ii) parallel with the plane of the adjacentpassageway inner wall, (iii) outwardly, such as away from the plane ofthe adjacent passageway inner wall or away from the first stream, or(iv) inwardly, such as towards from the plane of the adjacent passagewayinner wall or towards the first stream. Desirably, the location of thetabs beneath exit gap and the tab angles are selected such that thatthey do not extend directly into the flow of the first stream ofair-entrained fibers and/or do not extend inwardly of planes of theinner walls of the passageway. In a particularly desirable embodiment,the tabs extend outwardly from the walls such that they are both flushwith the CD extending walls 22 and/or 23 and extend parallel with thepassageway direction 26. While tabs are shown as extending from both thefirst and second opposed walls, it will be appreciated that the tabs canoptionally be positioned adjacent only one of the walls. The vortexgenerator, including the tabs, desirably extend along the entire CDlength of the walls although can optionally extend over less than theentire length of the walls, e.g. the tabs can extend along greater than60%, 70%, 80% or even 90% of the bottom of the walls in the CDdirection. For example, the vortex generator and/or tabs can extendbetween about 60-100%, 70-100%, 80-100% or even 90-100% of the bottom ofthe CD extending walls forming the passageway and/or chute.

The tabs can have one or more different shapes including triangular,Reuleaux triangular, square, rectangular, semicircle, semi-elliptical orother geometric or curvilinear shapes. For example, triangular shapedtabs 42 are shown in FIG. 3A, rectangular shaped tabs 42 are shown inFIG. 3B and sinusoidal shaped tabs 42 are shown in FIG. 3C. In a furtheraspect, the series of such shaped tabs can be presented in a regular andrepeating fashion having identical size and shaping; such structurewould present a generally wave-like structure such as a sine wave,triangular wave, square wave, rectangular wave, etc. However, the tabsneed not have identical size and/or shape. In certain embodiments, thetab shape will have one or more sharp corners as opposed to roundedfeatures; for example the corners such as formed from triangular orsquare shaped tabs. In certain embodiments, the tab shape may have oneor more corners, having an internal angle where the two sides meet,greater than about 30, 35, 40 or 45 degrees and less than about 110,100, 90 or 85 degrees. Further, the tabs on opposed walls can be alignedin the MD, staggered (partially off-set) or offset completely relativeto one another. For example, in reference to FIG. 3A, tabs 42 aextending below first wall 22 are fully off-set from tabs 42 b extendingbelow the opposed second wall 23 (not shown). Still further, and inreference to FIG. 3B, tabs 42 a extending below first wall 22 arepartially off-set from tabs 42 b extending from opposed second wall 23(not shown). Further in reference to FIG. 3B, tabs 42 a extending belowfirst wall 22 are partially aligned with tabs 42 b extending fromopposed second wall (not shown); in other words the tabs are partiallyoff-set from one another as seen from the MD. In reference to FIG. 3C,in this embodiment the tabs 42 on both on the opposed CD extending wallsare fully aligned in the MD and hence the opposed tab on the oppositewall cannot be seen. In such an embodiment the apertures 43 beneath theopposed walls are aligned in the MD and can be fully unoccluded in theMD direction on both sides. Still further, in certain embodiments, theedge of the tab, forming the overall or macro shape, may itself havemicroshapes therein such as having a micro-sinusiodal, scalloped,crenulated or serrated edges; e.g. a double serrated edge.

In certain embodiments, the tabs 24 can have a height (h) between about0.2 and about 4 cm, or between about 0.3 and about 2 cm, or even betweenabout 0.5 cm and about 1.5 cm. The height (h) is the distance measuredfrom the peak of the tab to lowest point in the flume or trough. Thespacing of the tabs will typically be influenced by their height, thusin certain embodiments the center-to-center spacing (d) can be betweenabout 0.75 and about 5 times the height or even between about 1 andabout 3 times the height. By way of example, in certain embodiments thetabs can have a center-to-center or spacing (d) of between about 0.4 toabout 10 cm, or between about 0.6 to about 8 cm or even between about 1cm and about 3 cm. In addition, in certain embodiments, the tabs canhave a thickness (t) as measured in the MD that is substantially thesame as or less than that of the CD extending walls of the chute. Forexample, the tabs can be less than about 90%, 50%, 30%, 10% or 5% of thethickness of the CD extending walls of the chute. In certainembodiments, the tabs can have a thickness of between about 0.5 mm andabout 30 mm although desirably the tabs will be relatively thin such ashaving a thickness between about 0.8 mm and 5 mm. Between the tabs areapertures or flumes 43 that allow movement of air generally orthogonalto the passageway direction 26 and/or parallel to the MD.

The vortex generator may be attached to the walls by one or more meansknown in the art such as, for example, through the use of adhesive,welds, bolts, screws or other fasteners. For ease of attachment andfabrication, and as best seen in reference to FIG. 2, the vortexgenerator may have a base 44 adjacent the bottom of the channel wall andthat extend behind the tabs 42. The base 44 extends outwardly or awayfrom the inner walls 22 a towards the opposed outer walls 22 b. However,it is important that the base or other elements not occlude the openspaces 43 located between the individual tabs 42. In this regard, theunoccluded space adjacent and behind the tabs allows air to travelbetween the tabs in a direction generally sidewardly or orthogonalrelative to the to the passageway direction. It is believed that as thefirst stream of air-entrained fibers pass the tabs, the air-entrainedfibrous stream adjacent the apertures starts to expand just prior to theair-entrained fibrous stream adjacent the tabs, resulting in rotationalenergy and movement that in-turn drives more aggressive or better mixingwith additional fibers introduced immediately below the vortexgenerator.

System and Method of Making the Composite Nonwoven

As shown in reference to FIG. 1, a schematic representation of anapparatus or system 10 is shown for use in practicing the method of thepresent invention. A stream of first fibers 12 are introduced into afirst stream of air 14 generated by a blower 15, e.g. fan, jet or otherlike apparatus. The stream of air 14 picks-up and/or carries the firstfibers 12 and forms a first stream of air-entrained fibers 16. The firstfibers 12 can be introduced into the process by one or more fibergenerators 13 a. In this regard, the fibers can be manufactured in-lineor can be previously manufactured and separated for introduction intothe process. With respect to pre-made fibers, equipment such as apicker, hammer-mill, or like equipment may be used to separate andintroduce the individual fibers into the air stream. Alternatively, thefibers may be made in-line.

The first stream of air-entrained fibers 16 is directed into the chute20 via the entrance gap 28. The velocity of the first fibers as theyexit the chute via the exit gap 30 and pass the vortex generator 40 isat least 50 M/second such as, for example, being between about 50M/second and about 200 M/second. Upon exiting the exit gap 30 andpassing adjacent and past the vortex generator 40, the first stream ofair-entrained fibers 16 will continue until impinged upon by a secondstream of air-entrained fibers 50. Second fibers 52 are picked-up and/orcarried by a second stream of air 54, generated by a second blower 13 b,and the second stream of air-entrained fibers 50 is directed towards thepath of the first stream 16. The first and second streams 16, 50intersect and the momentum and motion of the respective streams causethe first and second fibers 12, 52 to intermix and thereby form acomposite stream 60 comprising a mixture of both the first and secondfibers 12, 52. As noted above, the degree of mixing is enhanced in theMD and/or CD directions as a result of the additional lateral and/orrotational movement of the first fibers 12 imparted by the vortexgenerator 40. However, it will be noted that the degree and nature ofthe fiber mixing may be further influenced by additional aspects of theprocess such as, for example, controlling the angle of impingement, airspeeds, air temperature, forming distance and other aspects of theprocess. In certain embodiments, the impingement angle, i.e. thedirection of the second fiber stream relative to the direction of thefirst fiber stream, can be between about 90° and about 20° or betweenabout 80° and 35° or even between about 60° and 40°

The composite stream 60 is directed towards a forming surface 70. Theforming surface 70 can comprise any one of numerous known formingsurfaces such as for example a belt, wire, fabric, drum and so forth.Typically, it will be desirable for the forming surface to beforaminous. Where it is desired for the resulting nonwoven web to haveadditional texture, a forming surface having a desired topography may beused such as for example the forming surfaces described in U.S. Pat. No.5,575,874 to Griesbach et al., U.S. Pat. No. 6,790,314 to Burazin etal., U.S. Pat. No. 9,260,808 to Schmidt et al. and so forth. As iscommon for continuous manufacturing processes, the forming surface ismoved laterally under the chute and flowing streams of fibers. The ratethat the fibers are introduced, e.g. mass of fibers streamed or extrudedper second, is selected in combination with the speed of the formingsurface, i.e. M/second, to achieve a nonwoven having the desired basisweight. Aiding with the drawing of the composite fiber stream 60, andthe collection of the airflows, is one or more vacuums 72 positionedunder the forming surface 70 such that the forming surface 70 is betweenthe chute 20 and the vacuum 72. The vacuum helps draw the fibers ontothe forming surface as well as draws the entraining air through theforming surface and collects the same to prevent it from dislodging orimpacting the fibers once deposited.

Once deposited onto the forming surface 70, a nonwoven web 64 is formedthereon. In certain embodiments, the nonwoven web as deposited may havethe desired degree of integrity without any further treatments such asin instances where the second fibers are introduced into the impingementregion when still semi-molten. In instances where additional webintegrity is needed and/or desired, the web may be treated in one ormore ways to increase the degree of fiber entanglement, such as byhydroentangling, or to generate fiber-to-fiber bonding, such as throughthe use of adhesives, thermal bonding and so forth. In certainembodiments, the inter-fiber bonding may be achieved autogenously wherethermoplastic fibers are employed. For example, where bicomponent orbinder fibers are included within one of the fiber streams, after thenonwoven web has been deposited, it can be heated to a temperature at orabove the melting point of the binder fibers or low melting component inorder to create bonds at the fiber contact points. In still otherembodiments, additional bonding and increased web integrity may beachieved through the formation of thermal point bonding. In this regard,as is known in the art, the nonwoven may be passed through a nip formedby a pair of embossing rolls, wherein at least one of the rolls has apattern of protuberances or “pins” corresponding to the desired patternof bond points. Bonding may be used as desired to increase web integrityas well as create desired aesthetics and/or textural features in theweb. By way of example only, various embossing methods are shown anddescribed in U.S. Pat. No. 3,855,046 to Hansen et al.; U.S. Pat. No.5,620,779 issued to Levy et al; U.S. Pat. No. 6,036,909 to Baum; U.S.Pat. No. 6,165,298 to Samida et al.; U.S. Pat. No. 7,252,870 to Andersonet al. and so forth. The total embossed area will generally be less thanabout 50% of the surface area of the nonwoven web and more desirablywill be between about 2% and about 30% of the web or even between about4% and about 20% of the web.

In one particular aspect, and in reference to FIG. 4, the vortexgenerator and process of the present invention may be employed in themanufacture of a composite nonwoven web comprising a mixture ofmeltblown fibers and staple length fibers. In such a process, at leastone meltblown die head is arranged near the chute exit. Preferably twomeltblown die heads are employed, such as being positioned on opposedsides of the fiber stream exiting the chute. By way of non-limitingexample, suitable processes and techniques for forming such compositewebs are described in U.S. Pat. No. 4,100,324 to Anderson, et al.; U.S.Pat. No. 5,350,624 to Georger, et al.; and US Patent ApplicationPublication Nos. 2003/0200991 to Keck, et al., 2007/0049153 to Dunbar,et al., and 2009/0233072 to Harvey et al., all of which are incorporatedherein in their entirety by reference to the extent consistent herewith.

The staple length fibers, such as pulp fibers, may be introduced intothe chute 144 using equipment such as a picker roll 136 arrangementhaving a plurality of teeth 138 adapted to separate a mat or batt 140 offibers into the individual staple length fibers. Fibers can also, as iswell known, be introduced from bales (not shown). When employed, thesheets or mats 140 of fibers are fed to the picker roll 136 by a rollerarrangement 142. After the teeth 138 of the picker roll 136 haveseparated the mat of fibers into separate staple length fibers (notshown), the individual fibers are conveyed through a chute 144. Ahousing 145 encloses the picker roll 136 and provides a passageway orgap 148 between the housing 145 and the surface of the teeth 138 of thepicker roll 136. An air stream is supplied to the passageway or gap 148between the surface of the picker roll 136 and the housing 146 by way ofan air duct 150. The air duct 150 directs air downwardly through the gap148 entraining individual fibers into the chute 144. The air suppliedfrom the duct 150 serves to entrain lose fibers in the gap 148 and alsoremove fibers from the teeth 138 of the picker roll 136. A second airstream is introduced via air duct 152 that helps ensure that fibers areremoved from the picker teeth and directed back into the gap 148 andair-stream entering the top of the chute 144. The air supplies areselected to have sufficient quantity and speed to ensure that fibers areeffectively removed from the teeth of the picker and also that theentrained fibers are directed into and downwardly through the chute 144.The air may be supplied by any conventional arrangement such as, forexample, an air blower (not shown). It is contemplated that additivesand/or other materials may be added to or entrained in the air streamtogether with the individual fibers or to treat the fibers.

Still in reference to the embodiment shown in FIG. 4, a thermoplasticpolymer composition may be introduced into extruders 114 a and 114 bfrom corresponding pellet hoppers 112 a and 112 b. The extruders 114 aand 114 b each have an extrusion screw (not shown), which is driven by aconventional drive motor (not shown). As the polymer advances throughthe extruders 114 a and 114 b, it is progressively heated to a moltenstate due to rotation of the extrusion screw by the drive motor. Heatingmay be accomplished in a plurality of discrete steps with itstemperature being gradually elevated as it advances through discreteheating zones of the extruders 114 a and 114 b toward two meltblowingdies 116 a and 116 b, respectively. The meltblowing dies 116 and 118 maybe yet another heating zone where the temperature of the thermoplasticresin is maintained at an elevated level for extrusion.

When two or more meltblowing die heads are used, such as described inrelation to this embodiment, it should be understood that the fibersproduced from the individual die heads may themselves be different typesof fibers. That is, one or more of the size, shape, or polymericcomposition may differ, and furthermore the fibers may be monocomponentor multicomponent fibers. Alternatively and/or additionally, each diehead can extrude approximately the same amount of polymer per unit oftime or, as desired, one die head may have a higher extrusion rate thanthe other such that the proportion of fibers varies by side. Stateddifferently, in certain embodiments it may also be desirable to have therelative basis weight production skewed, such that one die head or theother is responsible for the majority of the meltblown fibers containedwithin the composite nonwoven web.

As is known with respect to the formation of meltblown fibers, highvelocity streams of air attenuate the melt-extruded fibers 120 a, 120 bexiting the die 116 a, 116 b. Each meltblowing die 116 a, 116 b ispositioned so that two streams of attenuating air per die converge toform a single stream of air which entrains and attenuates molten threads120 a, 120 b as they exit small holes or orifices 124 a, 124 b in eachmeltblowing die. The molten threads 120 a, 120 b are formed into fibersusually less than the diameter of the orifices 124. Thus, eachmeltblowing die 116 a and 116 b has a corresponding single stream 126 aand 126 b of air-entrained thermoplastic polymer meltblown fibers. Thestreams of air-attenuated meltblown fibers 126 a and 126 b containingpolymer fibers are directed to converge at an impingement zone 130.Typically, the meltblowing die heads 116 a and 116 b are arranged at anacute angle with respect to the staple fiber stream 134 exiting thechute 144.

The first stream 134 of air-entrained staple fibers, having beendirected through the chute 144 and past the exit gap 132 and vortexgenerator 170, is impinged upon by the two streams 126 a and 126 b ofthermoplastic polymer meltblown fibers 120 a and 120 b, respectively, atthe impingement zone 130. By merging the first stream 134 containing thestaple fibers between the two streams 126 a and 126 b of thermoplasticpolymer meltblown fibers 120 a and 120 b, all three gas streams convergein a controlled manner and create an intermixed composite stream 156.However, often the fiber streams are not uniformly mixed and instead agradient structure is obtained. Also, because the meltblown fibers 120a, 120 b remain relatively tacky and semi-molten after formation, themeltblown fibers 120 a and 120 b can simultaneously adhere and entanglewith the staple fibers upon contact therewith to form a coherentnonwoven structure upon deposition without the need for additionalbonding or treatment.

To convert the composite stream 156, comprising the combined stream ofair-entrained thermoplastic polymer fibers 126 a, 126 b andair-entrained staple fibers 134, into a fully coherent compositenonwoven structure 154, a collecting device is located in the path ofthe composite stream 156. The collecting device may be a foraminousforming surface 158 (e.g., belt, drum, wire, fabric, etc.) driven byrollers 160 and that is rotating as indicated by the arrow 162. Themerged streams 156 of meltblown fibers and staple fibers are therebycollected forming a coherent composite nonwoven web 154. A vacuum box162 is desirably employed to assist in drawing the composite stream ontothe forming surface 158 and removing the entraining air. The resultingnonwoven web 154 is coherent and may be removed from the forming surface158 as a self-supporting nonwoven material and thereafter furtherprocessed and/or converted as desired.

Fibers and Composite Webs

As noted above, the nonwoven webs may include staple length fibers andsuch fibers may comprise synthetic fibers, natural fibers orcombinations thereof. A wide variety of staple fibers are commerciallyavailable and the present invention is not believed limited with respectto the particular fiber selected. Selections may be made, as is known tothose skilled in the art, in order to achieve the desired webproperties, cost and so forth.

In certain applications it may be desirable for the staple fibers tocomprise absorbent fibers such as, for example, cellulosic fibers. Thecellulosic fibers may comprise traditional paper making fibers includingwoody fibers such as those obtained from deciduous and coniferous trees,including, but not limited to, softwood fibers, such as pine, fir, andspruce, and also hardwood fibers, such as eucalyptus, maple, birch, andaspen. Other papermaking fibers that can be used in the presentdisclosure include paper broke or recycled fibers and high yield fibers.Various pulping processes believed suitable for the production ofcellulosic fibers include bleached chemithermomechanical pulp (BCTMP),chemithermomechanical pulp (CTMP), pressure/pressure thermomechanicalpulp (PIMP), thermomechanical pulp (TMP), thermomechanical chemical pulp(TMCP), high yield sulfite pulps, and high yield Kraft pulps. Debondedfluff pulps are particularly well suited for use in the presentinvention. In addition, the cellulosic fibers may comprises non-woodyfibers, such as cotton, abaca, bamboo, kenaf, sabai grass, flax, espartograss, straw, jute hemp, bagasse, milkweed floss fibers, pineapple leaffibers and so forth. Still further, the cellulosic fibers may comprisesynthetic fibers derived from cellulosic materials such as, for example,viscose, Rayon, lyocell or other comparable fibers. Moreover, ifdesired, secondary fibers obtained from recycled materials may be used,such as fiber pulp reclaimed from sources such as, for example,newsprint, paperboard, office waste, etc. The fibrous sheet material cancomprise a single variety of cellulosic fibers or alternatively cancomprise mixture of two or more different cellulosic fibers. As is knownin the art, it is often desirable to employ mixtures of fibersespecially when utilizing recycled or secondary fibers. Regardless ofthe origin of the wood pulp fiber, the wood pulp fibers preferably havean average fiber length greater than about 0.2 mm and less than about 3mm, such as from about 0.35 mm and about 2.5 mm, or between about 0.5 mmto about 2 mm or even between about 0.7 mm and about 1.5 mm.

With respect to synthetic fibers, a wide variety of polymers may beused, such as polyolefins including for example ethylene, propylene, andbutylene polymers and blends and combinations thereof. In certainembodiments, the synthetic fibers may comprise polytetrafluoroethylene;polyesters, e.g., polyethylene terephthalate and so forth; polyvinylacetate; polyvinyl chloride acetate; polyvinyl butyral; acrylic resins,e.g., polyacrylate, polymethylacrylate, polymethylmethacrylate, and soforth; polyamides, e.g., nylon; polyvinyl chloride; polyvinylidenechloride; polystyrene; polyvinyl alcohol; polyurethanes; polylacticacid; and so forth. The polymeric composition may comprise a blend ormixture of two or more different polymers and include various additivesand fillers as is known in the art. Further, the fibers may comprisemonocomponent, multicomponent or multiconstituent fibers. The syntheticstaple fibers can have fiber length greater than about 0.2 mm including,for example, having an average fiber size between about 0.5 mm and about50 mm or between about 0.75 and about 30 mm or even between about 1 mmand about 25 mm.

The second fibers, although different from the first fibers in one ormore respects, may likewise comprise synthetic staple fibers such asthose described herein above. Alternatively, the second fibers may becontinuous fibers such as those formed from meltblowing, spunbonding orother fiber formation processes. The continuous fibers may also comprisepolymers similar to those described above with respect to the syntheticstaple fibers. With respect to the formation of meltblown fibers, theuse of propylene polymers is particularly preferred as offering a goodbalance of properties at relatively low cost. By way of example only,various polymers suitable for use in the manufacture of thethermoplastic nonwoven fibers include, but are not limited to, thosedescribed in U.S. Pat. No. 7,467,447 to Thomas, U.S. Pat. No. 9,194,060Westwood, U.S. Pat. No. 9,260,808 to Schmidt et al. and so forth.

In certain embodiments, the nonwoven web can include at least about 30%of the first fibers. For example, the first fibers, such as staplefibers, can comprise between about 25 and 90%, or between about 35 and85% or even between about 45% and about 80% of the nonwoven web.Further, in certain embodiments, the second fibers, can comprise atleast about 10% of the nonwoven web. For example, in certain embodimentsthe first fibers, such as continuous fibers, may comprise between about10% to about 75%, or between about 15% ad about 65% or even betweenabout 55% and about 20% of the nonwoven web. Generally speaking, theoverall basis weight of such composite nonwoven web can be in the rangeof from about 10 gsm (g/M²) to about 350 gsm, or from about 17 gsm toabout 250 gsm, or even from about 25 gsm to about 150 gsm.

In practicing the present invention it is possible to achieve nonwovenwebs having a higher MD and/or CD tensile strength as compared tononwoven webs made without the use of the vortex generator. Further, incertain embodiments, the use of the vortex generator can result in anonwoven web having zones of distinct basis weights extending in the MD;i.e. a nonwoven web having parallel alternating first and second zonesextending in the MD wherein the first zone has a higher average basisweight than the second zone. For example, the first zone (relative tothat of the second zone) may contain a higher percentage and amount ofthe first fibers. For example, the nonwoven fabric can have firstregions or zones extending in the MD with an average basis weight atleast about 5% higher than that of the second region and in certainembodiments can have an average basis weight between about 5%-20%, oreven between about 5-15% greater than that of the second zone. Incertain embodiments, the composite nonwoven web formed has first zonesextending in the MD and second zones extending in the MD wherein thefirst zone has both a higher basis weight than the second zone and ahigher percentage of the first fibers, e.g. staple or pulp fibers, thanthe second zone.

Optionally, the nonwoven web may be treated in one or more additionalways as desired. For example, surfactants may be applied to the web inorder to improve the ease with which water penetrates the web.Additionally and/or alternatively, the nonwoven web may be treated toimpart aesthetically pleasing and/or texture enhancing patterns to thenonwoven web. For example, the nonwoven web may be treated by one ormore embossing or bonding techniques known in the art that impartlocalized compression and/or bonding corresponding to one or moredesired patterns. In this regard, the base sheet can be embossed by theapplication of localized pressure, heat, and/or ultrasonic energy. Asfurther options, the nonwoven webs may, additionally or alternatively,be treated by various other known techniques such as, for example,stretching, needling, creping, and so forth. Still further, the nonwovenweb may optionally be plied with and/or laminated to one or moreadditional materials or fabrics.

Materials formed by the current process and techniques of the presentinvention have a wide array of applications. By way of example, thecomposite nonwoven webs may comprise a wiper including for example askin cleaning washcloth or wipe (e.g. face, hands or perineal cleaning)or a hard surface wipe. In a further application, the composite nonwovenwebs of the present invention can be used as an absorbent layer in apersonal care absorbent article including for example within a femininecare liner, diaper, incontinence garment, bib, sweatband, bandage and soforth.

EXAMPLES

Composite nonwoven webs, consisting of a mixture of polypropylenemeltblown fibers and softwood wood pulp fibers, were made using theprocess as described in U.S. Pat. No. 8,017,534 to Harvey et al. Theresulting nonwoven webs had a fiber ratio of 70:30 wood pulp fiber tomeltblown fiber. Samples were made using a vortex generator having atriangular wave pattern of either “small” triangular shaped tabs (1.4 cmwidth, 0.7 cm height) or with “large” triangular shaped tabs (2.5 cmwidth, 1.3 cm height). Samples were also made having tabs on the opposedCD extending chute walls either aligned (i.e. tab peaks of the opposedvortex generators were aligned in the MD) or offset (i.e. tab peaks ofone vortex generator aligned in the MD with the troughs of the opposedvortex generator). Samples were also made with the tab angle either at 0degrees (i.e. where the tab was parallel with the chute walls) or at 45degrees (i.e. where the tabs are angle inwardly towards and slightlyinto the fiber flow). In all instances the base of the tabs were flushwith the chute walls. The control was run without any vortex generator.

Tab Mean CD Mean MD Tab Alignment Peak Load Peak Load Example Tabs Angle(MD) (gf) (gf) A Small  0° Aligned 216.8 738.5 B Small 45° Aligned 197.3748.6 C Small  0° Offset 195.0 675.3 D Small 45° Offset 192.4 769.6 ELarge  0° Aligned 193.4 721.2 F Large 45° Offset 195.3 759.6 G Control —— 179.1 687.5

The control and inventive samples all had comparable levels of softness.However, the use of the vortex generators provided an increase in MDand/or CD strength without degradation of softness. In addition, it isnoted that Example E, and to a lesser extent Examples F and B, hadvisually discernable stripes with alternating regions having relativelyhigher and lesser amounts of pulp.

The composite nonwoven webs and the equipment and processes of makingthe same can, optionally, include one or more additional elements orcomponents as are known in the art. Thus, while the invention has beendescribed in detail with respect to specific embodiments and/or examplesthereof, it will be apparent to those skilled in the art that variousalterations, modifications and other changes may be made to theinvention without departing from the spirit and scope of the same. It istherefore intended that the claims cover or encompass all suchmodifications, alterations and/or changes.

What is claimed is:
 1. A method of making a composite nonwoven web comprising: providing a chute having at least first and second opposed walls that extend in a cross-direction that define a passageway and passageway direction and further define an exit gap; providing a series of spaced tabs extending outwardly from proximate the exit gap and further wherein adjacent the tabs are open spaces whereby air is allowed to flow sidewardly relative to the passageway direction; entraining first fibers in a first stream of air and thereby forming a first stream of air-entrained fibers; entraining second fibers in a second stream of air thereby forming a second stream of air-entrained fibers; directing the first stream of air-entrained fibers through the passageway in the passageway direction; directing the first stream of air-entrained first fibers through the exit gap and past the tabs thereby forming vortices in the first stream of air-entrained fibers; then directing the second stream of air-entrained fibers such that it impinges upon the first stream of air-entrained fibers wherein the second fibers and first fibers inter-mix and form a composite stream of air-entrained fibers; providing a moving forming surface under the exit gap; depositing the composite stream of air-entrained fibers onto the forming surface thereby forming a nonwoven web.
 2. The method of claim 1 wherein the velocity of the first stream of air-entrained fibers within the chute is greater than 50 M/second.
 3. The method of claim 1 wherein the tabs have a height between about 0.2 and about 4 cm.
 4. The method of claim 3 wherein the center to center distance of the tabs is between about 0.4 and about 10 cm.
 5. The method of claim 1 wherein the series of tabs and open spaces form a crenulate.
 6. The method of claim 1 wherein the tabs have a triangular shape.
 7. The method of claim 1 wherein the series of spaced tabs extends along at least 60-100% of at least one of the first and second walls.
 8. The method of claim 1 wherein the series of spaced tabs extend along at least 60-100% of both of the first and second walls.
 9. The method of claim 8 wherein the series of spaced tabs are positioned beneath the entire CD length of both of said first and second walls.
 10. The method of claim 8 wherein the tabs adjacent the opposed first and second walls are offset relative to one another in the machine direction.
 11. The method of claim 8 wherein the tabs adjacent the opposed first and second walls are aligned with one another in the machine direction.
 12. The method of claim 1 wherein the first fibers have an average length of between about 0.2 and about 3 mm.
 13. The method of claim 12 wherein the first fibers comprise cellulosic fibers.
 14. The method of claim 12 wherein the second fibers comprise thermoplastic polymer and are semi-molten when the second stream of air-entrained fibers impinges upon and mixes with the first stream of air-entrained fibers.
 15. The method of claim 1 wherein the greater inter-mixing of the first and second streams of fibers occurs regionally whereby first fibers are regionally driven deeper into the stream of second fibers and wherein the nonwoven web formed on the forming surface has alternating first and second rows, extending in the machine direction, whereby the first region has a greater weight percentage of first fibers than the second region.
 16. The method of claim 15 wherein the first rows contain at least 5% more first fibers than the second rows.
 17. The method of claim 1 wherein the first fibers comprise staple length fibers and the second fibers comprise continuous fibers.
 18. The method of claim 1 wherein the tabs extend at an angle +/−45 degrees relative to the passageway direction.
 19. The method of claim 1 wherein the tabs do not extend directly beneath the passageway.
 20. The method of claim 1 wherein the tabs are flush with an inner wall of the first or second wall and further wherein the tabs are angled away from the passageway. 